Project description:Red fruits are valued for their vitamin C and polyphenol content, but traditional heat preservation methods used in juice and nectar production can significantly reduce these components. Therefore, alternative non-thermal methods are explored to inactivate foodborne pathogens like Escherichia coli while maintaining the nutritional value. However, knowledge about the effects of these technologies on bacterial cells is limited. This study analyzed differentially expressed genes of E. coli ATCC 8739 inoculated in strawberry nectar after exposure to three treatments with two sets of parameters each, namely thermal treatment, high-pressure processing (HPP), and moderate-intensity pulsed electric field (MIPEF). The highest inactivation efficiency was achieved with HPP at 400 MPa, 1 min, reducing microbial counts by 5.0±0.3 log cfu/mL, and thermal treatment at 60°C, 200 s, achieving a reduction of 4.4±0.2 log cfu/mL, while no inactivation was observed with MIPEF at 6 kV/cm. Transcriptomic analysis showed that thermal and HPP treatments caused similar molecular stress responses in E. coli. In both cases, the most overexpressed genes encoded outer membrane proteins, which may lead to the activation of the envelope stress response. Despite no microbial inactivation was revealed after MIPEF treatment, strong transcriptomic responses were observed, particularly in genes related to membrane integrity and metabolic activity. Numerous overexpressed genes associated with ABC transporters, outer membrane proteins, and lipoproteins were identified, which could increase the strain’s virulence. This study provides insights into the stress response mechanisms induced by conventional and novel treatments. Nevertheless, further research is needed to investigate the long-term effects on bacterial populations.

Project description:This study investigated the impact of moderate electric field (MEF) and shear stress (SS) on the chemical profile of a blended fruit and vegetable juice using untargeted metabolomics. Samples underwent mild thermal treatment, MEF, and a combination of MEF and SS, with subsequent chemical changes analyzed through liquid chromatography-mass spectrometry (LC-MS). Principal component analysis revealed distinct clustering based on treatment type, indicating that processing with MEF and MEF+SS altered the juice metabolite composition compared to both fresh juice and sample subjected to mild thermal treatment. Notably, anthocyanins underwent degradation, with MEF and MEF+SS treatments resulting in increased rates of compound breakdown and/or oxidation. Furthermore, MEF and MEF+SS treated samples had higher levels of some phenolic acids, such as gallic acid and caffeic acid, suggesting enhanced bioaccessibility and bioavailability. These findings suggest that MEF, both with and without SS, induces significant non-thermal effects, contributing to the degradation or release of key metabolites. This work underscores the potential of MEF and MEF+SS technologies to modify food composition during processing, offering new opportunities for optimizing food quality.

Project description:According to the Canadian Food Inspection Agency and Health Canada, genetically modified crops are considered safe if they are substantially equivalent to a conventional crop in regards to agronomic, physiological and compositional characteristics. A recurring issue in safety assessment of genetically modified crops is the paucity of analytical methods to detect unintended or unexpected outcomes of genetic modification. Traditional targeted compound comparative analyses are limited in scope and capacity to detect unintended changes in chemical composition. This study explored the potential of using microarray technology to assess the substantial equivalence of gene expression profiles between genetically modified and conventional soybean cultivars. Different pre processing methods were applied to the raw expression data from the arrays, and clustering methods were used to try and differentiate the genetically modified cultivars from the conventional cultivars. Results showed that more variation existed between different strains of conventional cultivars than between conventional and genetically modified cultivars. For more information, please see: Cheng, K.C., Beaulieu, J., Iquira, E., Belzile, F.J., Fortin, M.G. and Strömvik, M.V. (2008). “Effect of transgenes on global gene expression in soybean is within the natural range of variation of their conventional counterparts.” Journal of Agricultural and Food Chemistry (in press) Experiment Overall Design: Five samples (biological replicates) of total RNA from each of the five different soybean varieties were selected for hybridization to Affymetrix Soybean GeneChips, for a total of 25 chips (following total RNA integrity assessment). Spike controls B2, bio-B, bio-C, bio-D and Cre-x were added to each hybridization cocktail. Arrays were washed and stained in an Affymetrix Fluidics Station prior to scanning on the Affymetrix GeneChip Scanner 3000. Image acquisition and processing was done with the Affymetrix Microarray Analysis Suite 5.0.

Project description:According to the Canadian Food Inspection Agency and Health Canada, genetically modified crops are considered safe if they are substantially equivalent to a conventional crop in regards to agronomic, physiological and compositional characteristics. A recurring issue in safety assessment of genetically modified crops is the paucity of analytical methods to detect unintended or unexpected outcomes of genetic modification. Traditional targeted compound comparative analyses are limited in scope and capacity to detect unintended changes in chemical composition. This study explored the potential of using microarray technology to assess the substantial equivalence of gene expression profiles between genetically modified and conventional soybean cultivars. Different pre processing methods were applied to the raw expression data from the arrays, and clustering methods were used to try and differentiate the genetically modified cultivars from the conventional cultivars. Results showed that more variation existed between different strains of conventional cultivars than between conventional and genetically modified cultivars. For more information, please see: Cheng, K.C., Beaulieu, J., Iquira, E., Belzile, F.J., Fortin, M.G. and Strömvik, M.V. (2008). Effect of transgenes on global gene expression in soybean is within the natural range of variation of their conventional counterparts. Journal of Agricultural and Food Chemistry. Keywords: Expression comparison between genetically modified cultivars

Project description:We report the application of miRNA next generation sequencing (NGS) for the analysis of impact of processing on miRNA in human breast milk, donated by 3 volunteers. MiRNA content of total and exosomal fraction was compared between unprocessed milk and sample subjected to either Holder (thermal) pasteurization (HoP) or elevated pressure processing (HPP). NGS reads were mapped to miRBase in order to obtain miRNA counts. Then, we analyzed differences in the miRNA abundance and function between raw and processed material. It was observed that both processing methods reduce number of miRNA reads and HoP is significantly more detrimental to miRNA than HPP.

Project description:Fresh fish are highly perishable food products and their short shelf-life limits their commercial exploitation, leads to waste and has a negative impact on aquaculture sustainability. New non-thermal food processing methods, such as High pressure (HP), are being investigated to prolong shelf-life while assuring high food quality. We applied several tools to evaluate the impacts of HP processing on European sea bass (Dicentrarchus labrax) fillets quality and shelf life. The data here presented includes visual and physical measurements of flesh quality and the microbiome and proteome profiles of control and HP-processed sea bass fillets (600MPa, 25ºC, 5min), after isothermal storage (2°C) for different periods ranging from 1 to 67 days. Color (L-, a- and b- values) change and texture (hardness, cohesiveness and adhesiveness) parameters were obtained by using appropriate colorimeter and texture analyser, respectively, during refrigerated storage. Bacterial diversity was analysed by Illumina high-throughput sequencing of the 16S rRNA gene in five pooled DNAs from control or HP-processed fillets after 1, 11 or 67 days and the raw reads were deposited in the NCBI-SRA database with accession number PRJNA517618. In addition, high-throughput sequencing of the internal transcribed spacer (ITS) region targeting yeast and moulds was run for control or HP-processed fillets at the end of storage (11 or 67 days, respectively), being deposited under SRA accession PRJNA517779. Quantitative label-free proteomics profiles were analysed by SWATH-MS (Sequential Windowed data independent Acquisition of the Total High-resolution-Mass Spectra) in myofibrillar or sarcoplasmic enriched protein extracts pooled for control or HP-processed filets after short (1d) or long-term (11-67 days) storage. These data support the findings reported in “High pressure processing of European sea bass (Dicentrarchus labrax) fillets and tools for flesh quality and shelf life monitoring” (Tsironi et al. 2019).

Project description:Environmental stress contributes to the outcome of infection by impacting both microbial virulence and host susceptibility to infection. Thermal processing, commonly used for decontamination of poultry in the food industry, may elicit sublethal stress on resistant serovars of Salmonella. We employed traditional heat shock temperatures (42 and 48ºC), similar to avian body temperature and poultry processing conditions, to study gene expression of Salmonella enterica serovar Typhimurium. Microarray analysis indicated that thermal shock at 42°C and 48°C induced expression of SPI-2 and SPI-5 genes, whose products are required for adhesion and survival. However, SPI-1 genes, responsible for invasion of Salmonella into host cells, were down-regulated following exposure to 42°C and 48°C. Bacterial adhesion assays showed greater adhesion of heat-stressed S. Typhimurium to Caco-2 cells compared to non-stressed bacteria. In addition, subjecting Caco-2 cells to mild heat shock (39°C), which is similar to human fever, enhanced host cell susceptibility to bacterial adhesion. Data indicate that thermal stress enhances bacterial colonization and host cell susceptibility to adhesion during S. Typhimurium infection.

Project description:As novel technologies allow for a substantial increase in the number of LC-MS run per day, proteomics sample preparation appears as new bottle-neck for throughput. To overcome this limitation, we introduce a novel strategy for positive pressure 96-well filter-aided sample preparation (PF96) on a commercial positive pressure solid-phase extraction unit allowing for a 5-fold reduction in lab-time. Similar as conventional FASP, PF96 allows for robust processing of protein amounts between 3 and 60 µg, with higher analyte recovery observed for higher protein loads (36-60 µg). Notably, even lower amounts can be processed reproducibly, but at the expense of loss of peptide signal intensity (~40 % of signal intensity for 3 µg compared to 60 µg ) - more pronounced for peptides of higher retention time (reversed phase) and higher share of the hydrophobic amino acids F, L, M, W. Processing of 40 technical replicates of mouse heart tissue lysate highlights its reproducibility with Pearson Product-Moment correlations of r=0.9992 and r=0.9891 on protein and peptide level, respectively, which is similar to the reproducibility of LC-MS for replicate injections of identical samples.

Project description:We characterized fission yeast cellular responses to a novel stress inducer, non-thermal atmospheric-pressure plasma.

Project description:Processing food and feed challenges official control e.g. by modifying proteins, which leads to significant underestimation in targeted, MS-based protein quantification. Whereas numerous studies identified processing-induced changes on proteins in various combinations of matrices and processing conditions, studying their impact semi-quantitatively on specific protein sequences might unveil approaches to improve protein quantification accuracy. Thus, 335 post-translational modifications (e.g. oxidation, deamidation, carboxymethylation, Amadori, acrolein adduction) were identified by bottom-up proteomic analysis of 37 bovine materials relevant in food and feed (meat, bone, blood, milk) with varying processing degrees (raw, spray-dried, pressure-sterilized). To mimic protein recovery in a targeted analysis, peak areas of marker and reference peptides were compared to those of their modified versions, which revealed peptide-specific recoveries and variances across all samples. Detailed analysis suggests that incorporating two modified versions additionally to the unmodified marker may significantly improve quantification accuracy in targeted MS-based food and feed control in processed matrices.